Methods to reduce current spikes in capacitive dc-dc converters employing gain-hopping

ABSTRACT

A capacitive voltage converter providing multiple gain modes comprising a switched capacitor array having a voltage input and a voltage output. A skip gating control coupled to the switched capacitor array and configured to control a switch resistance value of the switched capacitor array, and to control a switching sequence of the switched capacitor array. An override control coupled to the skip gating control and the switched capacitor array, the override control configured to detect transitions in a gain mode and to modify the switch resistance value of the switched capacitor array and the switching sequence of the switched capacitor array for a finite amount of time following the gain mode transition.

RELATED APPLICATIONS

This application claims benefit of U.S. Provisional Application No. 61/619,845, filed Apr. 3, 2012, entitled “Methods to Reduce Current Spikes in Capacitive DC-DC Converters Employing Gain-Hopping,” and is related to U.S. application Ser. No. 13/312,879, filed Dec. 6, 2011, entitled “System and Method for Capacitive DC-DC Converter with Variable Input and Output Voltages,” both of which are hereby incorporated by reference for all purposes as if set forth herein in their entirety.

TECHNICAL FIELD

The present disclosure relates to capacitive DC-DC converters, and more specifically to a system and method to reduce current spikes in capacitive DC-DC converters that employ gain hopping.

BACKGROUND OF THE INVENTION

Capacitive DC-DC voltage converters are known in the art. Although such voltage converters have known advantages for integrated circuit applications, they also have known disadvantages, such as limited capability to drive high current loads.

SUMMARY OF THE INVENTION

A capacitive voltage converter providing multiple gain modes comprising a switched capacitor array having a voltage input and a voltage output. A skip gating control coupled to the switched capacitor array and configured to control a switch resistance value of the switched capacitor array, and to control a switching sequence of the switched capacitor array. An override control coupled to the skip gating control and the switched capacitor array, the override control configured to detect transitions in a gain mode and to modify the switch resistance value of the switched capacitor array and the switching sequence of the switched capacitor array for a finite amount of time following the gain mode transition.

Other systems, methods, features, and advantages of the present disclosure will be or become apparent to one with skill in the art upon examination of the following drawings and detailed description. It is intended that all such additional systems, methods, features, and advantages be included within this description, be within the scope of the present disclosure, and be protected by the accompanying claims.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Aspects of the disclosure can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views, and in which:

FIG. 1 is a diagram of a system for a capacitive dc-dc converter with variable input and output voltages in accordance with an exemplary embodiment of the present disclosure;

FIG. 2 is a diagram showing gain modes as a function of voltage in accordance with an exemplary embodiment of the present disclosure;

FIG. 3 is a diagram of a current response and of an efficiency response of a system in accordance with an exemplary embodiment of the present disclosure;

FIGS. 4A and 4B are flow charts of an algorithm for controlling a mode of operation of a DC-DC converter in accordance with an exemplary embodiment of the present disclosure;

FIG. 5 is a diagram showing the effect of R_(SW) on current in accordance with an exemplary embodiment of the present invention;

FIG. 6 is a diagram of capacitor configurations for phase transitions in accordance with an exemplary embodiment of the present invention;

FIG. 7 is a diagram showing current overshoot and reverse flow conditions that can occur with uncorrected phase transitions;

FIG. 8 is a diagram showing current response when applying an override system in accordance with an exemplary embodiment of the present invention; and

FIG. 9 is a diagram showing current flow as a function of phase and gain mode in accordance with an exemplary embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE INVENTION

In the description that follows, like parts are marked throughout the specification and drawings with the same reference numerals. The drawing figures might not be to scale and certain components can be shown in generalized or schematic form and identified by commercial designations in the interest of clarity and conciseness.

Capacitive DC-DC converters (“charge-pumps”) are becoming increasingly common for generation of ASIC power supplies at low or moderate current levels. Because they require no external inductive components, they offer an inexpensive bill of materials, a small footprint, and limited electromagnetic interference concerns.

A control loop can be used for capacitive DC-DC converters to regulate the charge-pump output voltage. While “skip mode” regulation (which consists in stopping the charge-pump switching activity when the output voltage exceeds the target voltage) and “gain hopping” regulation (which dynamically adjusts charge-pump gain as a function of input voltage, output voltage and loading conditions) are known, skip mode regulation without gain control is very inefficient if the input voltage varies over wide voltage ranges, and gain hopping involves significant power losses at the transitions between low and high gain and is only effective for certain combinations of input and output voltages.

Furthermore, because of their pulsed nature, capacitive DC-DC converters tend to generate large spikes on the input and output currents, which can be detrimental to other circuitry in the system by means of ground bounce noise and radiated emissions. While “linear mode” analog loops that continuously modulate the resistance of the charge-pumps switches as a function of the output current can be used to address this problem, it is not known how to combine skip mode (which is used for overall output voltage control and to achieve high-efficiency at light current loads) with gain hopping (which is used for high-efficiency over wide voltage ranges) and with linear mode (which is used for controlling current spikes).

Accordingly, a system and method for controlling a DC-DC converter that combines skip mode, gain hopping and switch resistance control is disclosed. A skip comparator stops switching activity in a capacitor array whenever the output voltage exceeds the target voltage plus a small overhead voltage ΔV. In parallel, a hop comparator selects one of two gain modes for the switched cap array: a higher gain that is used when V_(OUT) is less than V_(TARGET), and a lower gain that is used when V_(OUT) is greater than V_(TARGET).

To support an input voltage that can vary over a wide range, more than two gain modes are utilized. In one exemplary embodiment, four gain modes are utilized, namely:

mode D0 with a gain=1

mode D1 with a gain=2/3

mode D2 with a gain=1/2

mode D3 with a gain=1/3

Gain selection logic which is based on the outputs of two analog to digital converters representing V_(IN) and V_(TARGET) is used to determine which of two gain modes are required. For example, if V_(IN)=3.3 V and V_(TARGET)=1.0V, the charge-pump can operate either in mode D2 (gain=1/2) or mode D3 (gain=1/3). The decision between D2 and D3 is a function of the hop signal, as discussed further herein.

The current flowing into the charge pump at any given time is proportional to ((G×V_(IN))−V_(OUT))/R_(SW), where G is the charge-pump gain and R_(SW) is the resistance of the switched capacitor array. While R_(SW) should be kept sufficiently low in order for the charge-pump to be able to deliver the largest required output current in the worst-case conditions for V_(IN)/V_(OUT) (such as when ((G×V_(IN))−V_(OUT)) is small), under more favorable conditions (such as when ((G×V_(IN))−V_(OUT)) is large) a small value of R_(SW) can cause unnecessarily high current peaks and does not improve the overall power efficiency.

In order to reduce current peaks, an “R_(SW) selection table” is introduced. This table is used to compute ((G×V_(IN))−V_(TARGET))) by combining the A/D outputs and gain mode information (D0-D3) to select a higher value for the R_(SW) parameter when possible. R_(SW) can be modulated in discrete steps by splitting each switch of the capacitor array into an array of smaller switches, each providing a resistance multiple of R_(SW).

Simulations show that the current peaks can be reduced significantly (such as by 3 to 4 times normal) by having eight discrete levels for R_(SW), with minimal impact to the overall power efficiency. Based on these simulations, finer quantization for R_(SW) does not appear to be necessary. The selection of the optimal value for R_(SW) is made by way of a lookup table having V_(IN), V_(TARGET), maximum load current that needs to be driven and gain mode as inputs.

In most scenarios, switch resistance is not a constant but varies as a function of V_(IN) in a non-linear manner. In one exemplary embodiment, the switches can be driven much more efficiently (lower resistance) at a higher voltage than at a lower voltage. The dependence of R_(SW) on V_(IN) can also be included in the lookup table without any further hardware requirements, as only the content of the lookup table needs to be updated. In this manner, the charge-pump can take full advantage of the lower resistance available at higher V_(IN) when necessary, while properly scaling the switch resistance up when possible.

This exemplary architecture is quite simple and inexpensive in terms of hardware requirements. The skip gating block consists of one AND gate for each switch control signal. The gain selection logic is relatively simple digital combinational logic. The lookup table is quite small in size. For this design, each ADC is 3-bit resolution and the table stores 128×3-bit words. The analog to digital converter (ADC) used for V_(IN) can be of low resolution, such as a 3-bit ADC, with minimal impact to the overall efficiency curve. A second ADC block connected to V_(TARGET) is usually unnecessary as the V_(TARGET) information is already available in digital format for a charge-pump with programmable output voltage.

The disclosed SHL mode uses two comparators instead of one in order to decouple the hop control from the skip control. Using one comparator, the charge pump gain is increased as soon as the skip duty ratio exceeds 80% so the charge pumps ends up working in a higher gain setting more frequently than is necessary, which causes a drop in efficiency. Using two comparators allows the charge-pump to stay in skip mode (at a lowest gain setting) even as the duty ratio approaches 100%. In addition, switch resistance control is added to the control loop. An analog feedback loop for switch resistance control is replaced with an open-loop discrete control, to eliminate analog components from the design (filter, variable-resistance switches), and to allow co-existence with gain-hopping.

FIG. 1 is a diagram of a system 100 for a capacitive dc-dc converter with variable input and output voltages in accordance with an exemplary embodiment of the present disclosure. System 100 can be implemented in hardware or a suitable combination of hardware and software, and can be one or more software systems operating on a hardware platform. As used herein, “hardware” can include a combination of discrete components, an integrated circuit, an application-specific integrated circuit, a field programmable gate array, or other suitable hardware. As used herein, “software” can include one or more objects, agents, threads, lines of code, subroutines, separate software applications, two or more lines of code or other suitable software structures operating in two or more software applications or on two or more processors, or other suitable software structures. In one exemplary embodiment, software can include one or more lines of code or other suitable software structures operating in a general purpose software application, such as an operating system, and one or more lines of code or other suitable software structures operating in a specific purpose software application.

System 100 includes switched capacitor array 102, which is a suitable combination of series and/or parallel connected switched capacitors that allows the values of the resistance and the topology of the switched-capacitor network to be controllably modified. In one exemplary embodiment, switched capacitor array 102 can be the combination of series and parallel connected switched capacitors shown in FIG. 4.5 of “Design of High Efficiency Step-Down Switched Capacitor DC/DC Converter,” Mengzhe Ma, Oregon State University (May 21, 2003), which is hereby incorporated by reference, or other suitable switched capacitor arrays.

Switched capacitor array 102 receives input voltage V_(IN) and outputs voltage V_(OUT). By controlling the gain and resistance of switched capacitor array 102, the current consumed by switched capacitor array 102 and the efficiency of switched capacitor array 102 can be controlled, so as to minimize the current consumed and to maximize the efficiency. Controls for selecting switches that control the resistance and capacitor settings of switched capacitor array 102 are received from R_(SW) selection table 104 and skip gating 106. As discussed above and further herein, R_(SW) selection table 104 is used to select values of resistance for switched capacitor array 102, and skip gating 106 is used to control topology and switching activity for switched capacitor array 102

R_(SW) selection table 104 receives inputs representing the target voltage V_(TARGET) from analog to digital converter 112, the input voltage V_(IN) from analog to digital converter 110 and the gain mode control signal from gain selection logic 108, and generates a resistor selection setting as a function of those inputs. An example of values for R_(SW) selection table 104 is provided below. The values range from 1 ohm to 8 ohms, and higher resistance values are chosen when V_(IN) is larger. This exemplary lookup table can be selected when the gain mode is D3, with similar tables being used for each of the other gain modes (such as D0, D1 and D2).

TARGET V_(IN) (volts) <2.8 2.8-3.0 3.0-3.2 3.2-3.4 3.4-3.6 >3.6 0.7-0.8 1 Ω 2 Ω 4 Ω 5 Ω 6 Ω 8 Ω 0.8-0.9 1 Ω 1 Ω 2 Ω 3 Ω 5 Ω 6 Ω 0.9-1.0 1 Ω 1 Ω 1 Ω 1 Ω 3 Ω 5 Ω 1.0-1.1 1 Ω 1 Ω 1 Ω 1 Ω 1 Ω 2 Ω

Gain selection logic 108 receives an input representing target voltage V_(TARGET) from analog to digital converter 112, an input representing input voltage V_(IN) from analog to digital converter 110 and the output of comparator 116, which receives V_(TARGET) and V_(OUT) and which generates and output indicative of whether V_(TARGET) is larger or smaller than V_(OUT). Gain selection logic 108 outputs a control signal to R_(SW) selection table 104 and skip gating 106 indicating which gain region the system should be operating in (D₀ through D₃).

Skip gating 106 receives the output from gain selection logic 108 and a signal from comparator 114, which compares V_(OUT) and V_(TARGET) plus a small overhead voltage ΔV. Capacitor 118 is coupled to the output V_(OUT) in order to reduce voltage ripple.

Override 120 is used to alter the normal switching activity to reduce current spikes. One problem associated with gain-hopping is that the voltage on the fly capacitors has to change as the mode of operation changes. A sudden voltage change results in several problems:

The presence of large current spikes on the input and output nodes as the fly capacitors are quickly charged/discharged. Current spikes can generate noise on the power/ground lines and impact performance for other components in the system.

A loss of power efficiency as the large current flows through the (resistive) capacitor switches, as power dissipation equals I²×R.

Supply pumping in the case of negative current spikes, as the current is being pushed into the input supply.

EMI (conducted emissions).

For instance, when the charge-pump is in D3, the steady-state voltage on the fly capacitors is approximately Vin/3. In D2, the steady-state voltage on the fly capacitors is V_(IN)/2. Assuming the gain transitions from D2 to D3 between PH2 and PH1, as PH1-D3 starts, the two fly capacitors are connected in series and try to drive V_(OUT) to 0 V. Since the bulk capacitor on V_(OUT) is already charged to V_(IN)/3, a large current spike will flow out of V_(OUT) and into V_(IN) as shown in FIG. 9. As shown in FIG. 9, when transitioning from state D2 to state D3, it is better to be in phase two to avoid current spikes on V_(IN). Likewise, in a transition from D3 to D2, it is better to be in phase one.

In one exemplary embodiment, override 120 alters the PH1-PH2 switching pattern shown in FIG. 6 immediately after the gain transition. For instance, one of the two phases can be forced for a certain number of cycles to allow the capacitors to change their voltage in the most favorable state (i.e. avoid drawing currents from the output node), such as by overriding a clock signal that is provided to the capacitor switches for a predetermined number of clock cycles. In another exemplary embodiment, override 120 alters the normal switch resistance immediately after the gain transition. For instance, the switch resistance can be increased for a certain number of clock cycles to reduce the magnitude of the current spikes.

In the previous example, when transitioning from D2 to D3, the switch matrix is forced to PH2 for a predetermined number of clock cycles, such as 4 clock cycles, until the capacitor voltage is close to V_(DD)/3. In addition, the switch resistance can be increased by a suitable amount, such as a factor of 3, for a predetermined number of clock cycles, such as two clock cycles. When normal switching activity resumes, the overshoot and reverse current conditions shown in FIG. 7 no longer exists. Similar measures can be applied to the D3-D2 transition. The end result is shown in FIG. 8, which avoids the overshoot condition through the use of increased switch resistance and which avoids the reverse current conditions by overriding the normal clock operation.

The number of clock cycles and the resistance value depends on the gain transition as shown in the table below:

Force Num of Clk Switch Gain Transition phase cycles resisitance D0 → D1/D1 → D0 None 0 No change D1 → D2 Ph1 2 Increase by a factor N1 D2 → D1 No change 0 No change D2 → D3 Ph2 2 Increase by a factor N1 D3 → D2 Ph1 2 Increase by a factor N2

To improve the efficiency, for some input voltages and load current, the charge pump (switched capacitor DC-DC converter) is controlled to hop between the minimum gain and a higher gain, so that the charge pump can deliver enough charge to support a large load current at a desired output voltage without significantly reducing the efficiency. The charge pump runs at a lower gain for a few clock cycles, and runs at a higher gain for another few clock cycles. Consequently, the converter keeps hopping between different gains to make the average gain as low as possible to maximize the efficiency.

When the charge pump hops between gain configurations, though, there tends to be a difference in amount of voltage across the fly capacitors during the gain transitions. A sudden change in voltage during the first gain transition leads to a spike of current on the capacitor nodes which can cause EMI problems at the input Vin, due to conductive emission.

In order to prevent the current spike, the clock signal can be forced high in one of the phases, long enough to pre-charge the fly capacitors to the most appropriate voltage, so that when the next phase arrives, the current spike is lower than cases where the clock signal continues unmodified.

In operation, system 100 provides for the combination of a skip mode control for a DC-DC converter (which is used for overall output voltage control and to achieve high-efficiency at light current loads) with gain hopping mode of operation for a DC-DC converter (which is used for high-efficiency over wide voltage ranges) and with a linear mode of operation for a DC-DC converter (which is used for controlling current spikes). System 100 thus provides for improved efficiency and reduced current requirements.

FIG. 2 is a diagram 200 showing gain modes as a function of voltage in accordance with an exemplary embodiment of the present disclosure. Diagram 200 shows four exemplary gain modes that can be utilized to improve the efficiency of a DC-DC voltage converter, namely:

mode D0 with a gain=1

mode D1 with a gain=2/3

mode D2 with a gain=1/2

mode D3 with a gain=1/3

Gain selection logic 108 is used to determine which of two gain modes are required as a function of the inputs discussed above or other suitable inputs. For example, if V_(IN)=3.3 V and V_(TARGET)=1.0 V, the charge-pump can operate either in mode D2 (gain=1/2) or mode D3 (gain=1/3). The decision between D2 and D3 is a function of the hop signal. In the lower portion of a gain region, a hop mode of operation is selected, whereas in the higher portion of a gain region, a skip mode of operation is selected. The mode of operation is automatically selected depending on loading conditions: for example, if the charge-pump can provide the required output current using only gain mode D3, it will normally not use gain mode D2, thus achieving the highest possible power efficiency.

FIG. 3 is a diagram of a current response 300A and of an efficiency response 300B of a system such as system 100, in accordance with an exemplary embodiment of the present disclosure. Current response 300A increases in magnitude as the efficiency response follows a gain curve downward with increasing input voltage, then reduces in magnitude in the region between gain curves. By controlling the value of the switch resistance R_(SW) of the switched capacitor bank, the current peak can be maintained at a level that is a factor of two or more less than the current peaks seen in prior art systems.

FIGS. 4A and 4B are flow charts of algorithms 400A and 400B for controlling a mode of operation of a DC-DC converter in accordance with an exemplary embodiment of the present disclosure. Algorithms 400A and 400B can be implemented in hardware or a suitable combination of hardware and software, and can be one or more software systems operating on a hardware platform.

Algorithm 400A begins at 402, where a value of V_(IN) is received and digitized. In one exemplary embodiment, the analog value of V_(IN) can be received at an analog to digital converter and can be converted into a binary value representing the analog voltage magnitude. The algorithm then proceeds to 406 and 418.

Likewise, at 404, an analog value of a target output voltage V_(TARGET) is received and digitized. In one exemplary embodiment, the analog value of V_(TARGET) can be received at an analog to digital converter and can be converted into a binary value representing the analog voltage magnitude. The algorithm then proceeds to 406 and 418.

At 406, a gain region is selected, such as based on the value of V_(IN) or other suitable variables. The algorithm then proceeds to 408, the output voltage V_(OUT) is compared to the target voltage V_(TARGET), such as by providing the voltages as inputs to a comparator and generating an output. If the value of V_(OUT) is larger than the target voltage V_(TARGET), then the algorithm proceeds to 412, where a low gain mode is selected, otherwise, the algorithm proceeds to 410 where a high gain mode is selected. The algorithm then proceeds to 418, where a switch resistance is selected, and to 414, where it is determined whether V_(OUT) is greater than V_(TARGET) plus a small overhead voltage ΔV. If V_(OUT) is greater than V_(TARGET) plus a small overhead voltage ΔV, the algorithm returns to 402 and 404, otherwise, the algorithm proceeds to 416, where switching activity is performed.

Algorithm 400B shares common elements with algorithm 400A, but instead of 408 to 412, provides 418 to 422 as described herein. At 418, it is determined whether a gain mode has changed. If the gain mode has not changed, the algorithm proceeds to 414, otherwise, the algorithm proceeds to 420, where a normal resistance setting is overridden, and the algorithm then proceeds to 422, where a normal switching pattern is overridden, such as to maintain a higher resistance value and to prevent a sudden change in capacitance that would result in a current spike, as described in greater detail herein. The algorithm then proceeds to 414.

In operation, algorithms 400A and 400B allow a capacitor array in a DC-DC converter to be controlled so as to improve efficiency, reduce current to the capacitor array, and for other suitable purposes.

FIG. 5 is a diagram 500 showing the effect of R_(SW) on current in accordance with an exemplary embodiment of the present invention. The top line (502) shows an example of the current drawn as a function of voltage when the switch resistance uniformly equals 1 ohm, and the bottom line (504) shows an example of the current for the same voltage profile when the switch resistance is allowed to vary as described herein. By reducing the current requirements for the capacitor array, the efficiency of the DC-DC converter is improved.

It should be emphasized that the above-described embodiments are merely examples of possible implementations. Many variations and modifications may be made to the above-described embodiments without departing from the principles of the present disclosure. All such modifications and variations are intended to be included herein within the scope of this disclosure and protected by the following claims. 

What is claimed is:
 1. A capacitive voltage converter providing multiple gain modes comprising: a switched capacitor array having a voltage input and a voltage output; a skip gating control coupled to the switched capacitor array and configured to control a switch resistance value of the switched capacitor array, and to control a switching sequence of the switched capacitor array; and an override control coupled to the skip gating control and the switched capacitor array, the override control configured to detect transitions in a gain mode and to modify the switch resistance value of the switched capacitor array and the switching sequence of the switched capacitor array for a finite amount of time following the gain mode transition.
 2. The capacitive voltage converter of claim 1 further comprising gain selection logic coupled to the skip gating control and a resistance look-up table and configured to provide a gain value to the skip gating control and the resistance look-up table.
 3. The capacitive voltage converter of claim 1 further comprising a resistance look-up table having a target voltage value input and an output that is selected to control the switch resistance value of the switched capacitor array as a function of the target voltage value input.
 4. The capacitive voltage converter of claim 1 further comprising a resistance look-up table having an input voltage value input and an output that is selected to control the switch resistance value of the switched capacitor array as a function of the input voltage value input.
 5. The capacitive voltage converter of claim 2 wherein the gain selection logic comprises an output voltage value input and is configured to generate the gain as a function of the output voltage value input.
 6. The capacitive voltage converter of claim 1 wherein the skip gating control comprises an output voltage value input and is configured to control the capacitance value of the switched capacitor array as a function of the output voltage value input.
 7. The capacitive voltage converter of claim 1 further comprising a resistance look-up table having a target voltage value input and an output that is selected to control the switch resistance value of the switched capacitor array as a function of a target voltage value input and the input voltage.
 8. The capacitive voltage converter of claim 1 further comprising a resistance look-up table having a target voltage value input and an output that is selected to control the switch resistance value of the switched capacitor array as a function of a target voltage value input, the input voltage and a gain value, wherein the switch resistance value is scalable based on an expected load current setting.
 9. The capacitive voltage converter of claim 1 wherein the switched capacitor array is configured to operate in two or more gain regions.
 10. The capacitive voltage converter of claim 1 wherein the switched capacitor array is configured to provide two or more selectable resistance values for at least one switch in the switched capacitor array.
 11. A method for controlling a capacitive voltage converter comprising: receiving an input voltage; selecting a gain region for a switched capacitor array as a function of the input voltage and an expected output voltage; selecting a skip gating control setting for the switched capacitor array as a function of the gain region; selecting a first resistance setting of the switched capacitor array as a function of the input voltage; selecting a switching sequence of the switched capacitor array; detecting a transition in a gain mode; and modifying the first resistance setting and the switching sequence of the switched capacitor array for a predetermined amount of time following the gain mode transition.
 12. The method of claim 11 further comprising selecting the gain region for the switched capacitor array as a function of an output voltage of the switched capacitor array.
 13. The method of claim 11 further comprising selecting the gain region for the switched capacitor array as a function of a target voltage for an output of the switched capacitor array.
 14. The method of claim 11 further comprising selecting the skip gating control setting for the switched capacitor array as a function of an output voltage of the switched capacitor array.
 15. The method of claim 11 further comprising selecting the skip gating control setting for the switched capacitor array as a function of a target voltage for an output of the switched capacitor array.
 16. The method of claim 11 further comprising selecting the resistance setting of the switched capacitor array as a function of the input voltage and a target voltage for an output of the switched capacitor array.
 17. The method of claim 11 further comprising selecting the resistance setting of the switched capacitor array as a function of the input voltage, a gain value for the switched capacitor array and a target voltage for an output of the switched capacitor array.
 18. A method for controlling a capacitive voltage converter comprising: receiving an input voltage; selecting a gain region for a switched capacitor array as a function of the input voltage and an expected output voltage; selecting a skip gating control setting for the switched capacitor array as a function of the gain region; selecting a switching sequence of the switched capacitor array; detecting a transition in a gain mode; and modifying the first resistance setting and the switching sequence of the switched capacitor array for a predetermined amount of time following the gain mode transition.
 19. The method of claim 18 further comprising selecting a first resistance setting of the switched capacitor array as a function of the input voltage. 